SU1557532A2 - Panoramic meter of frequency of radiosignals - Google Patents

Abstract

The invention relates to radio metering technology and can be used to search, detect and measure the carrier frequency of radio signals in a wide frequency range. The purpose of the invention is to improve the accuracy of measuring the frequency of signals by suppressing spurious signals received via combinational channels - it is achieved by comparing the amplitudes of the signal from a superheterodyne receiver and the signal of an additionally inserted serial circuit. Amplitude detector 27 - Video amplifier 28 - Comparison unit 29. 1 ... 25, passes to the oscillographic indicator 26 through the unipolar gate 30 only when receiving a signal via the main channel. 1 il.

Description

The invention relates to measuring technique and can be used to search, detect, and measure the carrier frequency of radio signals in a wide frequency range.

The drawing shows a structural diagram of a panoramic frequency meter of radio signals. *

The aim of the invention is to increase the accuracy of measuring the carrier frequency of the signals by suppressing false signals (interference).

Panoramic radio frequency meter comprises a receiving antenna 1, 2 g'onerator sweep oscillator 3, phase shifter 4, mixers 5 and 6, the variable phase shifters 7 and 8, amplifiers 9 and 10, intermediate frequency, narrow-band filters 11 and _{20 December} amplitude detectors 13 and 14 , subtractor 15, low-pass filter 16, inverse amplifier 17, phase detector 18, low-pass filter 19, inverse amplifier 20, phase shifter ₂ 5 body 21, adder 22, amplitude detector 23, video amplifier 24, calibrator 25, CRT 26, amplitude detector 27, video amplifier 28, comparison unit 29, unipolar valve 30,

In the panoramic radio signal frequency meter, two reception channels are connected to the output of the receiving antenna 1, each of which consists of a series-connected mixer 5 (6), the second input of which is connected to the high-. 35 by means of a local oscillator-3, adjustable phase shifter 7 (8), the second input of which is connected to the output of the calibrator 25, an intermediate frequency amplifier 9 (10), a narrow-band filter 11 (12), and an amplitude detector 13 (14), output;

which through series-connected subtractor 15, low-pass filter 16 and inverse amplifier 17 is connected to the second input of intermediate-frequency amplifier 9 (10), a phase detector 18, the second input of which is connected to the output of narrow-band filter 12, is connected to the output of narrow-band filter 11, filter 19 lowpass and inverted amplifier 20, whose two outputs are connected to second inputs of variable phase shifters 7 and 8, to the output of intermediate frequency amplifier 10 po- ⁵ ^ therefore connected phase shifter 21, an adder 22, the second input of which is connected to the output of the intermediate frequency amplifier 9. The amplitude detector 23, the video amplifier 24, the comparison unit 29, the unipolar valve 30, the output of which is connected to the vertical electrode of the oscilloscope indicator 26, the horizontal electrode of which is connected to the output of the scan generator 2, are connected in series, the second input of the comparison unit 29 is connected to the output of the video amplifier 24, output the receiving antenna 1 is connected to the input of the amplitude detector 27,

The suppression of false signals (interference) received via Raman channels is based on the use of a detector receiver, consisting of an amplitude detector and a video amplifier, and a superheterodyne receiver, consisting of two parallel channels, each of which consists of a mixer, an intermediate frequency amplifier, and common adders, a detector and video amplifier, and the total gain of the superheterodyne receiver when receiving signals through combinational channels is always less than the gain when receiving on the basis of primary and mirror channels due to additional losses in the mixers during the combination conversion. If the total gain of the detector receiver is chosen in such a way that it is less than the gain of the superheterodyne receiver when receiving signals on the main and mirror channels and more when receiving signals on the combination channels, then the comparison unit generates a positive voltage in the first case and a negative voltage in the second case which is not passed by a unipolar valve.

Panoramic radio frequency meter works as follows,

The search for signals in a given frequency range is carried out using a sweep generator 2, which periodically according to a sawtooth law changes the local oscillator 3 setting. At the same time, the generator 2 controls the horizontal sweep of the beam of the oscilloscope indicator 26, which is used as the frequency axis. For the convenience of using such a frequency axis, the tuning of the local oscillator 3 and the beam sweep are linear,

In this case, the frequency scale will be uniform along the entire length of the scan line.

The received signal from the output of the receiving antenna 1 is supplied to the first inputs of the mixers 5 and 6 and the amplitude detector 27. Moreover, the first signal of the mixer 6 receives the specified signal through the phase shifter 4 by 90 °. The oscillator 3 voltage is applied to the second inputs of the mixers 5 and 6. At the outputs of the mixers 5 and 6, the frequencies of the combination frequencies are generated. The first inputs of the amplifiers 9 and 10 of the intermediate frequency through the adjustable phase shifters 7 and 8, respectively, from the output of the calibrator 25 receive a harmonic calibrated signal, From the outputs of the amplifiers 9 and 10 of the intermediate frequency, the calibration signals are allocated by narrow-band filters 11 and 12, and after detection in the detectors 13 and 14 to the subtractor 15 of the amplitude identification system, In the case of inequality of the transmission coefficient coefficients of the receiving channels, the voltage (positive or negative) appears at the output of the subtractor 15, ond through lowpass filter 16 and an inverse amplifier January 7 acts on the second inputs of the amplifiers 9 and 10 of the intermediate frequency by changing their transmission coefficients such that the output voltage of the subtractor 16 converges to zero. In this case, the transmission coefficients of the amplifiers 9 and 10 of the intermediate frequency are almost the same at the frequency of the calibration signal. From the outputs of the narrow-band filters 11 and 12, the calibration signals are supplied to a phase identification system consisting of a phase detector 18, a low-pass filter 19, an inverse amplifier 20, and two phase-controlled adders 22, which generates a voltage that, after detection in the detector 23 and amplification in the video amplifier 24, at the second input, block 29 of comparison.

At the same time, the received signal from the output of the receiving antenna 1 goes to the input of the detector receiver, consisting of g from the amplitude detector 27.

and video amplifier 28. From the output of the last detected and amplified signal is fed to the input of the comparison unit 29. Since * the total gain of the detector receiver when receiving signals through the main channel is less than the gain of the superheterodyne receiver, then the comparator 29 generates a positive voltage, which, having passed the unipolar valve 30, is fed to the vertical electrode of the oscilloscope indicator 26, to the horizontal electrode of which voltage generator 2 sweep. Unipolar valve 30 passes only positive impulses. A pulse (frequency mark) is formed on the screen of the oscilloscope indicator 26, the position of which on the horizontal scan uniquely determines the carrier frequency of the detected signal,

The operation of the meter described above corresponds to the case of receiving signals on the main channel. If the signal is received via the mirror channel, then the voltages supplied to the two inputs of the adder 22 are compensated at its output. In this case, the identity of both channels is ensured automatically using an identification system. Therefore, a false signal (interference) received on the mirror channel at a frequency of 60 ^ is suppressed. If the false signal (interference) of the converters 7 and 8. If there is a phase non-identity of the receiving channels, a voltage (positive or negative) appears at the output of the phase detector 18, which acts through the low-pass filter 19 and the inverse amplifier 20 on the third inputs of the phase shifters 7 and 8, changing the phase shifts of the calibration signals so that the output voltage of the phase detector 18 tends to zero. Thus, the phase identification of the receiving channels is achieved. At the output it is passed through the combination channels, the total gain of the detector receiver will be greater than the gain of the superheterodyne receiver and at the output of the block it is comparable. In Fig. 29, a negative voltage is formed, which is not passed by the unipolar valve 30. Therefore, a false signal (interference) received through 55 combination channels is suppressed.

Claims (1)

SUMMARY OF THE INVENTION Panoramic measuring instrument of the frequency of radio signals according to auth. No. 1290192. characterized in that, in order to improve the accuracy of measuring the carrier frequency of the signals, a fourth amplitude detector, a second video amplifier, a comparison unit and a unipolar valve, the output of which is connected to the vertical electrode of the oscilloscope indicator, are connected in series, the second input of the comparison unit is connected with the output of the first video amplifier, the input of the fourth amplitude detector is connected to the output of the receiving antenna. Compiled by B, Novoselov Editor L, Veselovskaya Tehred L. Serdyukov Mr. Corrector.Shekmar Order 7 GB Circulation 555 Subscription VNIIIPI of the State Committee for Inventions and Discoveries at the State Committee for Science and Technology 113035, Moscow, Zh-35, Raushskaya nab., D. 4/5 Production and Publishing Plant Patent, Uzhgorod, st. Gagarina, 101